DE60127333T2 - spinal implant - Google Patents

Description

The The present invention relates to spinal implants for osteosynthesis devices and in particular a spinal implant.

In The past years have been numerous researches and developments made to a spinal implant to provide for deviations in orientation, angularity and the penetration depth of adjacent screwed in spaced vertebrae spinal implants adapt.

One such implant is disclosed in U.S. Pat. Patent 5,154,719. This device comprises a head section with a vertical Branching pair, inside a thread and a U-shaped recess and a screw portion extending from the head portion protrudes. The two branches take a connecting rod on, wherein the branches are held by an annular element. In this process step, some problems occur in the exact Alignment of the U-shaped Recesses of the spaced vertebral body screwed spinal implants, the angularity of the spinal implants and the depth of the spinal implants on that to an undesirable Fix the implants and the connecting rod. Of the Screw portion is further formed of a solid material and only in the vertebral body screwed. Accordingly, the fixation of the spinal implant unstable and subject to penetration into the vertebral body an unwanted, effect influenced by external forces, when the forces on the vertebral body Act.

U.S. Patent 5,879,351 discloses a spinal osteosynthesis device, the at least one connecting rod, pedicle screws and deformable fittings includes. In this prior art, the individual pedicle screws from the same aforesaid Material formed, and a problem in the reliable fixation of Pedicle screw in the vertebral body is also found. Furthermore, every single deformable connector an elongated opening, through a head portion of the screw extends and is elastic between a cylindrical base and a nut with a predetermined Spaced distance, the Ab was a relative movement of the connecting rod allows. Due to this arrangement, the spinal implant has a large number on components that lead to a complicated structure and increased costs.

U.S. Patent 5,129,388 discloses a spinal implant having an anchorable screw portion, which has a solid structure.

EP 784 967 discloses a metal or titanium-shaped spinal implant comprising an anchorable screw portion with a hollow body.

In known techniques it was common a plug by means of a tool holding device in the spinal implant contribute. In practice, there are two types of vertical Branches shaped head portions, namely a first head portion type with an internal thread, and a second head section type with a External thread. In the first type, the plug is in the internal thread of the head section screwed. This loosens the two branches, which makes it difficult becomes the connecting rod in the spinal implant firmly lock. In contrast, in the second type the plug on the external thread screwed the head section. Here, the outer periphery points the plug a hexagonal shape, and a drive tool with a hexagonal groove is made with the outer hexagonal wall of the Tamping engaged to turn the plug. In this Case becomes a claim space to rotate the drive tool elevated, because the drive tool has a larger outside diameter as the stopper has. Under these conditions, if two spinal implants are screwed into adjacent, closely spaced vertebrae, the impaired outer diameter the drive tool the adjacent plug of the spinal implant, causing problems in the rotation of the drive tool occur.

Summary the invention

The The present invention has been made to cope with the various disadvantages overcome the known devices and therefore it is an object of the present invention to provide a spinal implant for one To provide osteosynthesis device.

According to the present invention, there is provided a spinal implant according to claim 1 for an osteosynthesis device, wherein the spinal implant comprises a vertebral connecting rod for connecting adjacent vertebral bodies. The spinal implant comprises an implant body having a head portion having a threaded portion and a rod holder recess with an outwardly opening for receiving the connecting rod, and an anchored for screwing into the vertebral body anchored screw portion, gekop with the head portion of the implant body ping holding plugs to hold the connecting rod and a bar movement stabilizing device disposed at least in the bar holding recess or in the holding plug to allow rotational movement of the connecting bar in the bar holding recess while maintaining the freedom of movement of the connecting bar.

One Drive tool for a spinal implant with an implant body and an anchorable screw portion, and a nut member, which is screwed onto a head portion of the implant body and the an upper wall with a trained Werkzeugingriffsnut comprises a prolonged Shank and a tubular tool end having a substantially same diameter as that of the nut member, wherein the tool end has an engagement segment that is adapted to engage with the on the upper wall of the nut member to reach molded engagement groove.

A mother leadership to lead a nut element of a spinal implant with an implant body and an anchorable screw portion, and for guiding a Drive tool with a lower end, which with a nut engagement tip is formed, wherein a vertebral connecting rod by a Couple in vertebral body screwed spinal implants held is comprising a handle portion, and a cylindrical hollow shaft, which extends from the handle portion and is adapted to a penetration of a drive tool in the handle portion to enable, the cylindrical shaft a lower distal end formed with a rod engaging segment is to engage with the connecting rod and this to hold the lower distal end in a fixed position, and a threaded bore located on the rear side of the bar engaging segment is shaped to temporarily that Include nut element therein. The cylindrical shaft allows the Drive tool such a passage that the nut engaging tip in engagement with the guided in the cylindrical shaft nut passes to the nut member from the threaded bore to the implant body of the vertebra to move.

Other Aspects and advantages of the invention will become apparent from the following description in conjunction with the associated Drawings that are the principles of the invention, for example.

Short description the drawings

1 Fig. 10 is a schematic view of an osteosynthesis device incorporating a first preferred embodiment of a spinal implant according to the present invention, the spinal implant having a connecting rod for connecting spaced vertebral bodies by a plurality of spinal implants;

2 Fig. 10 is a side view illustrating the arrangement relationship between the plurality of spinal implants and the connecting rod connected thereto;

3 Fig. 10 is an enlarged front view of the first preferred embodiment of the spinal implant according to the present invention;

4 is a cross-sectional view of the spinal implant of 3 ;

5 is another cross-sectional view of the spinal implant of 3 ;

6 is a left side view of the spinal implant of 3 ;

7 Fig. 10 is an enlarged front view of a second preferred embodiment of a spinal implant according to the present invention;

8th Fig. 10 is an enlarged front view of a third preferred embodiment of a spinal implant according to the present invention, showing the connecting rod in the connected state with the spinal implant of the third preferred embodiment;

9 is an enlarged front view of a nut member that is a part of the spinal implant of 8th is;

10 is an enlarged plan view of the nut member of 8th ;

11 is an enlarged bottom view of the nut element of 8th ;

12 is an enlarged front view of a drive tool, which is specifically designed for use in the nut member of 8th suitable is,

13 Fig. 10 is an enlarged view showing the arrangement relationship between the spinal implant and a nut guide according to the present invention;

14 is a side view of the osteosynthesis device of 13 ;

15 is an enlarged exploded view of the nut guide of 13 ; and

16 is an enlarged side view of the nut guide of 13 ,

Full Description of the Preferred Embodiments

Referring to the drawings, in particular to the 1 and 2 , a spinal osteosynthesis device, generally with 10 marked, shown on individual vertebral bodies 12 was applied to several vertebral bodies 12 connect to.

The spine osteosynthesis device 10 includes an elongated vertebral connecting rod 14 passing through a pair of spinal implants 16 a first preferred embodiment according to the present invention is fixed. Each of the spinal implants 16 penetrates a vertebral body 12 in a manner which will be described in more detail below. The connecting rod 14 is made of a stretchable, elastically deformable material that has high elastic resilience to provide needed elastic deformation to accommodate deviations in the placement, angularity and penetration depth of the implant 16 to enable.

With reference to the 3 and 4 includes the spinal implant 16 a cylindrical implant body 18 to the connecting rod 14 Locally fix, and one longitudinally from the implant body 18 extending and screwed into the vertebral body 12 adapted, anchorable screw section 20 (see. 1 and 2 ).

The anchorable screw section 20 has an internal connection cavity 22 and a plurality of spinal openings 24 on, with each of the spinal openings 24 comprises a longitudinally extending longitudinal slot. Each longitudinal slot 24 extends transversely through the anchorable screw portion 20 from one side to the other and communicates with the internal connection cavity 22 To bone ingrowth in the connecting cavity 22 to enable. Therefore, the anchorable screw portion 20 a plurality of circumferentially spaced, elongated wall segments 26 on through the inner connecting cavity 22 and the plurality of longitudinal slots 24 be limited, wherein elastic deformation of the anchorable screw portion 20 is provided for adjusting any positioning of the Gewindeab section, by allowing an effective attachment without affecting the bone attachment.

A head section of the implant body 18 is with a U-shaped mounting recess 28 , which opens outward, and an internal threaded hole 30 formed, with the threaded hole 30 in the longitudinal direction over a position near the rod holder recess 28 extends. A disc-shaped nut element 32 gets into the inner tapping 30 screwed, causing the connecting rod 14 in the rod holder recess 28 is held.

A bottom wall 34 the rod holder recess 28 includes, as in 5 and 6 shown a bar movement stabilization device 35 with a beveled engagement surface 36 directly in the rod holder recess 28 arranged to pivot a movement of the connecting rod 14 in the rod holder recess 28 while maintaining the freedom of movement of the connecting rod 14 to enable. For this purpose, the bevelled engagement surface 36 slightly inclined at the positions that come from the axis center of the implant body 18 at an angle θ from the axis of the connecting rod 14 perpendicular to the axis of the implant body 18 are slightly shifted.

With this arrangement, it becomes the connecting rod 18 allows to perform pivotal movements within a range, by the beveled engagement surface 36 the rod holder recess 28 of the implant body 18 is defined. Because of the beveled engagement surface 36 the bar movement stabilization device 35 in the mounting recess 28 of the implant body is arranged, the connecting rod 14 tend.

Although the connecting rod 14 in an axis center of the implant body 18 comprehensive plane is inclined, the beveled engagement surface 35 modifiable such that the connecting rod 14 in a slight way in a the central axis of the implant body 18 tilting plane is tilted. In particular, like a dashed line in 6 shows, has the support recess 28 inclined engagement surfaces 40 on that in an in 6 left-to-right longitudinal direction except for the threaded portion 38 are formed.

With the above-mentioned arrangement, the plurality of spinal implants becomes 16 , as in 1 and 2 shown in such a way in the individual vertebral bodies 12 screwed and anchored that to two implant bodies 18 belonging bar support sections 28 aligned and both ends of the connecting rod 14 from the implant bodies 18 be recorded. In a subsequent step, the nut elements become 32 according to the thread proportions 30 the implant body 18 screwed, making the two ends of the connecting rod 14 firmly held and locked in the required position.

Due to the individual elongated, in the screw section 20 shaped wall segments 26 it will be the screw section 20 allows in the vertebral body 12 with a reduced diametric size due to the inward elastic deformation of the individual elongate segments 26 penetrate, reducing the penetration of the implant 16 is relieved. Once the penetration of the anchorable screw section 20 is done, widen the individual elongated wall segments 26 Due to restoring forces to their original position, thereby early improved fixation of the screw section 20 in the vertebral body 12 done in a highly reliable manner. Due to the provision of the plurality of through the longitudinal slots 24 limited spinal openings and the internal connection cavity 24 allow the spinal implants 16 Furthermore, a bone ingrowth into the connecting cavity 24 thereby further improving the attachment of the implant.

In the case that the two ends of the connecting rod 14 in the mounting recess 28 the implant body 18 be mounted after the multiple spinal implants 18 firmly in the vertebral bodies 12 have been secured in one of the aforementioned ways, and if the rotational position of the support recesses 28 the multitude of spinal implants 16 not aligned with each other, can be one of the spinal implants 16 be slightly rotated. In addition, as the depth of penetration of the plurality of spinal implants increases 16 differs from one another and has a faulty height alignment is the connecting rod 14 suitably along the tapered surfaces 36 partially deformable, due to the slight vertical deviation of the bottom walls of the plurality of in the vertebral bodies 12 penetrated spinal implants 16 compensate.

In other words, even if a slight height deviation between the bottom walls 34 the adjacent spinal implants 16 is present, is the connecting rod 14 reliably adaptable to this deviation, thereby providing in an easy and simplified manner, an improved engagement of the connecting rod in the plurality of spinal implants.

7 shows a second preferred embodiment of a spinal implant according to the present invention, wherein like parts have the same reference numerals as those in FIG 1 to 5 have used.

The spinal implant in 7 differs from the arrangement of the spinal implant of the first preferred embodiment in that the implant body 18 a rod holder recess 40 having a longitudinally extending, elongated opening and having a distal end of the implant body 18 a laterally extending tool engagement groove 42 Has. The spinal implant 16 of the second preferred embodiment has the same advantages as those of the aforementioned first preferred embodiment. Other features of the second preferred embodiment of the spinal implant 16 are identical to those of the first preferred embodiment, and accordingly, for the sake of simplicity, a detailed description of the second preferred embodiment of the spinal implant is hereby made 16 waived.

8th to 11 show a third preferred embodiment of a spinal implant according to the present invention. The spinal implant 16 in 8th includes an implant body 18 and an anchorable screw portion 20 that has a lot of small openings 46 which extends in a plane perpendicular to the axis of the screw portion 20 extend to allow bone ingrowth therein. The implant body 18 has a lower with an external thread 50 shaped end, on the one in an upper wall with a Werkzeugingriffsnut 56 trained nut element 52 is screwed. The implant body 18 also has a U-shaped mounting recess 54 on, with a spherical engagement segment 14a a connecting rod 14 engages the pivoting movement into engagement.

How best in 10 can be seen, the implant body 18 a pair of upright support segments 18A . 18B on, these being correspondingly large spaces 62 Provide and each has an arcuate cross-section. This will see the upright support segments 18A . 18B an open distal end of the kind that the connecting rod 14 a pivoting movement relative to the central axis of the spinal implant 16 is enabled when the spherical engaging segments 14A in the U-shaped recess 54 being held.

The nut element 52 has a ring shape with an internal thread, which is engageable with an external thread 50 of the implant body 18 is. An upper side of the nut element 52 has a plurality of Werkzeugingriffsnuten 52 on, which cross in a lateral direction. How best in 9 and 10 can be seen, takes the annular nut member 52 thus a central rotation 58 on, which is coaxial with the nut element 52 extends. A lower end of the central rotation shaft 58 is integral with a rod support member 60 formed, which has a central, spherical groove 60a and a pair of laterally extending arcuate retaining grooves 60b includes. As in 9 shown, the rod support member protrudes 60 down from a lower distal end of the nut member 52 out. The rod support element 60 has a radial, substantially to a diameter of the nut member 52 Same length and a lateral, slightly smaller width than that of the rod holder grooves 54 , An upper end of the central rotation shaft 58 has an annular flange 58a having a substantially same shape as that of the rod support member 60 on.

In 8th and 12 becomes a drive tool 70 for turning the nut element 52 shown. The drive tool 70 includes a tubular, hollow tool end 72 and an elongated shaft 74 rising up from the tubular body 72 extends. A lower end of the tubular body has a plurality of substantially axially extending engagement segments 72a on, for an engagement with the in the upper wall of the nut element 52 molded Werkzeugingriffsnuten 56 are adjusted. The tubular body 72 is the shape that it is essentially to the nut element 52 same diameter has.

With reference to the aforementioned arrangement, the anchorable screw portion first penetrates 20 of the spinal implants 16 into the vertebrae and then the connecting rod 14 and the spherical engagement segment 14a in the rod holder groove 54 of the implant body 18 arranged. In the next step, the rod support element becomes 60 in engagement with the rod support groove 54 of the implant body 18 brought and the nut element on the external thread 50 of the implant body 18 screwed. The nut element 52 is through the drive tool 70 turned so that the nut element 52 while it is fixed, with engaging teeth 72a of the drive tool 70 in engagement with the Werkzeugingriffsnuten 56 of the nut element 52 are located. With the help of the drive tool 70 this drive mechanism is improved, whereby a simple fastening operation of the nut member 52 in the implant body 18 provided. Because the tubular body 72 as previously discussed, substantially the same diameter as the nut member 52 and there is an outer periphery of the tubular body 72 of the drive tool 70 does not interfere with an outer periphery of an adjacent retaining plug, attachment operations of the driving tool 70 with respect to the adjacent, arranged in a limited space holding plug improved in a simple manner. The tool engagement grooves 56 are not on the in 8th and 9 shown limited special, but may have any other configuration such as a bore.

13 to 16 show a driving tool in conjunction with a spinal implant 16 having an arrangement identical to the first preferred embodiment, except that the retaining plug 32 a non-annular, hexagonal engagement groove 32A Has. An upper end of the drive tool 78 has a handle portion 78a and a lower one with a tool end 78b molded part a hexagonal nut engagement tip 78c on. The drive tool 78 is combined with a nut guide 80 used a handle section 84 and a cylindrical hollow shaft 82 includes. The grip section 84 has an inner guide hole 84a , which is for a recording of the grip section 78a of the drive tool 78 is adjusted. The cylindrical shaft 82 has an axially extending through hole 86 for guiding the drive tool 78 on. A lower end of the cylindrical shaft 82 has an internal threaded hole 88 , a nut guide room 90 , an intervention hall 92 and one for receiving the connecting rod 14 adapted rod engagement recess 94 on. Several prepared mounting rods 98 are fixed with a mounting base 96 connected to corresponding nut elements 32 provisionally support on the upper end of the bars. The nut elements 32 have corresponding hexagonal Eingriffsnute 32a on.

The variety of spinal implants will be put into operation 16 in turn in the vertebral bodies 12 attached and the connecting rod 14 suitable in the rod holder recess 28 of the implant 16 arranged. In a subsequent step, the nut guide 80 on one of the on the mounting rod 98 applied nut elements 32 placed so that the nut element 32 through the nut guide hole 90 the nut guide 80 to be led. The nut element 32 This is done with the nut guide 80 held, and the nut guide 80 becomes a like in 13 moved operating position shown. In this case, the rod engagement recess becomes 94 the nut guide 80 with the connecting rod 14 aligned so that the upper part of the implant body with the Eingriffführungsbohrung 92 the nut guide 80 on a like in 13 engages shown manner. Thereafter, the drive tool 78 through the nut guide 80 so far inserted that the engagement tip 78c with the tool engagement groove 32a of the nut element 32 engages and then the An driving tool 78 turned to the nut element 32 in the implant body 18 of the spinal implant 16 to unscrew until the nut element 32 with the connecting rod 14 got in contact. Consequently, the nut member becomes 32 in a simple and highly reliable manner in the implant body 18 secured without misalignment or causing problems.

• (A) Das Wirbelsäulenimplantat umfasst einen Implantatkörper, um eine vertebrale Verbindungsstange zu halten, und einen verankerbaren, sich vom Implantatkörper longitudinal erstreckenden und zur Verankerung in einem Wirbelkörper angepassten Schraubenabschnitt. Der verankerbare Schraubenabschnitt weist eine Vielzahl von Spinalöffnungen auf, um darin Knocheneinwuchs zu ermöglichen, woraus sich eine verbesserte Befestigung des Wirbelsäulenimplantats ergibt. Jede der Spinalöffnungen umfasst einen sich longitudinal erstreckenden Schlitz oder eine sich lateral erstreckende Bohrung, die sich vollständig von einer zu der anderen Seite erstreckt.
• (B) Der verankerbare Gewindeabschnitt kann ebenfalls einen inneren Verbindungshohlraum aufweisen, der mit den Spinalöffnungen kommuniziert und sich longitudinal durch den Gewindeabschnitt erstreckt, um darin Knocheneinwuchs zu erlauben. Mit dieser Anordnung kann das Wirbelsäulenimplantat frühzeitig in einer geeigneten Befestigungslage in dem Wirbelkörper und in einer Folgephase aufgrund des Knocheneinwuchses in den Spinalöffnungen und dem inneren Verbindungshohlraum weiterführend fest verankert werden. Daraus resultiert eine hinsichtlich des Wirbelkörpers zuverlässige Befestigung des Wirbelsäulenimplantats über einen längeren Zeitraum.
• (C) Ein Kopfabschnitt des Implantatkörpers weist eine Stangenelement-Stabilisierungseinrichtung zum Halten der Verbindungsstange hinsichtlich den angrenzenden Wirbelsäulenimplantaten auf, um unterschiedliche Ausrichtungen zwischen einem Stangenhalterungs-Abschnitt und der Verbindungsstange, der Höhe des Stangenhalterungs-Abschnitts und der Winkligkeit und Eindringtiefe der verankerbaren Schraubenabschnitte anzupassen. Dadurch kann die Verbindungsstange mit den angrenzenden Wirbelsäulenimplantaten auf leichte Weise abgestützt werden, ohne irgendwelche komplizierten, mühevollen Ausrichtungen oder Einstellungen der Winkligkeit und der Eindringtiefe der verankerbaren Schraubenabschnitte zu verursachen.
• (D) Das Wirbelsäulenimplantat umfasst ferner ein Mutternelement, das konzipiert ist, um in einen Kopfabschnitt eines Implantatkörpers geschraubt zu werden, wobei das ein Stangenhalterungs-Element umfassendes Mutternelement die Verbindungsstange in dem Implantatkörper hält, während eine verschwenkende Bewegung der Verbindungsstange unter Bewahrung einer ausgeglichenen Beweglichkeit ermöglicht wird, um Positionsversatz oder fehlerhafte Ausrichtungen zwischen den angrenzenden Wirbelsäulenimplantaten zu kompensieren.
• (E) Ein Antriebswerkzeug wird verwendet, um das Mutternelement im Verhältnis zu dem Implantatkörper zu drehen, wobei das Antriebswerkzeug wenigstens ein Eingriffssegment aufweist, das in Eingriff mit einer Eingriffsnut des Mutternelementes gelangt und im wesentlichen einen gleichen Durchmesser als den des Mutternelementes aufweist, wodurch dem Antriebswerkzeug ermöglicht wird, das Mutternelement eines der Wirbelsäulenimplantate ohne Beeinträchtigung des angrenzenden Mutternelements des anderen Wirbelsäulenimplantats, das zu dem erstgenannten eng angeordnet ist, auf einfache Weise anzutreiben.
• (F) Eine Mutternführung wird vorgeschlagen, um zuverlässig das Mutternelement zu führen, damit es leicht in dem verankerten Wirbelsäulenimplantat in höchst zuverlässiger Weise bewegt werden kann, wobei ebenfalls ein Antriebswerkzeug durch die Mutternführung geführt wird, um eine Eingriffsspitze des Antriebswerkzeugs mit der Eingriffsnut des Mutternelementes des Wirbelsäulenimplantats genau eingreifen zu lassen. Infolgedessen kann das Mutternelement problemlos mit dem Implantatkörper innerhalb eines kurzen Zeitraumes verbunden werden, ohne eine Drehung des Implantatkörpers relativ zu dem Wirbelkörper zu verursachen.

The spinal implant, drive tool, and nut guide provide numerous advantages over the prior art methods, such as:

• (A) The spinal implant comprises an implant body for holding a vertebral connecting rod and an anchorable screw portion longitudinally extending from the implant body and adapted for anchoring in a vertebral body. The anchorable screw portion has a plurality of spinal openings to allow bone ingrowth therein resulting in improved attachment of the spinal implant. Each of the spinal openings includes a longitudinally extending slot or bore extending completely from one to the other side.
• (B) The anchorable threaded portion may also have an internal connection cavity communicating with the spinal openings and extending longitudinally through the threaded portion to allow bone ingrowth therein. With this arrangement, the spinal implant can be firmly anchored firmly in an appropriate mounting position in the vertebral body and in a subsequent phase due to the bone ingrowth in the spinal openings and the internal connection cavity early on. This results in a reliable fixation of the spine implant over a longer period with respect to the vertebral body.
• (C) A head portion of the implant body has a rod member stabilizing means for holding the connecting rod with respect to the adjacent spinal implants to accommodate different orientations between a rod support portion and the connecting rod, the height of the rod support portion, and the angularity and penetration depth of the anchorable screw portions. Thereby, the connecting rod with the adjacent spinal implants can be easily supported without causing any complicated, laborious alignments or adjustments of the angularity and the penetration depth of the anchorable screw portions.
• (D) The spinal implant further comprises a nut member designed to be screwed into a head portion of an implant body, the nut member comprising a rod support member holding the connecting rod in the implant body while pivotally moving the connecting rod while maintaining balanced mobility is allowed to compensate for positional misalignment or misalignments between the adjacent spinal implants.
• (E) A drive tool is used to rotate the nut member relative to the implant body, the drive tool having at least one engagement segment that engages an engagement groove of the nut member and has a substantially equal diameter to that of the nut member, thereby providing the nut Driving tool is made possible to easily drive the nut member of one of the spinal implants without affecting the adjacent nut member of the other spinal implant, which is closely arranged to the former.
• (F) A nut guide is proposed to reliably guide the nut member to be easily moved in the anchored spinal implant in a highly reliable manner, also driving a driving tool through the nut guide to engage an engaging tip of the driving tool with the engaging groove of the nut member of the spine implant to intervene exactly. As a result, the nut member can be easily connected to the implant body within a short period of time without causing rotation of the implant body relative to the vertebral body.

The previous description of the preferred embodiments of the invention was submitted to the principles to illustrate the invention and not to the invention to limit the individual embodiments shown. For example, although the preferred embodiments are shown as such and have been described that the anchorable screw section of the spinal implant a spinal opening from a longitudinal slot or has a plurality of laterally extending bores, can the spinal opening all other suitable configurations such as an elongated opening or have an elliptical bore.

Claims (8)

Spine implant ( 16 ) for an osteosynthesis device with a vertebral connecting rod ( 14 ) for connecting adjacent vertebral bodies ( 12 ), comprising: an implant body ( 18 ) having a Kopfab cut with a threaded area ( 30 ; 38 ) and a rod holder recess ( 28 ), which outwardly for receiving the connecting rod ( 14 ) and a longitudinally extending from the head portion and for screwing into the vertebral body ( 12 ) adapted, anchorable screw section ( 20 ) having; a nut element ( 32 ; 52 ), which are in the threaded area ( 30 ; 38 ) of the head section for holding the connecting rod ( 14 ) is bolted; and a bar movement stabilizing device ( 35 ), at least in the rod holder recess ( 28 ) or in the nut element ( 32 ; 52 ) is arranged to a rotational movement of the connecting rod ( 14 ) in the rod holder recess ( 28 ) while maintaining the freedom of movement of the connecting rod ( 14 ); characterized in that the anchorable screw portion ( 20 ) a plurality of axially extending along an axis of the threaded portion spinal openings ( 24 ), an inner formed in the axial direction of the threaded portion and with the spinal openings ( 24 ) communicating connection cavity ( 22 ), and a plurality of longitudinally extending wall segments (FIG. 26 ), which between the inner connecting cavity ( 22 ) and the spinal openings ( 24 ) are formed; and that the wall segments ( 26 ) have an elastic deformation property, the penetration of the anchorable screw portion ( 20 ) in the vertebral body ( 12 ) with a reduced diametric size. Spinal implant according to claim 1, wherein the spinal opening ( 24 ) is formed in an axially extending along an axis of the threaded portion longitudinal slot. A spinal implant according to claim 1, wherein the rod support recess ( 28 ) has a U-shaped profile with a semicircular bottom wall, and wherein the bar movement stabilization device ( 35 ) one on the bottom wall of the rod holder recess ( 28 ) formed beveled engagement surface ( 36 ) having a pivoting movement of the connecting rod ( 14 ) in the rod holder recess ( 28 ). Spinal implant according to claim 1, wherein the spinal openings ( 24 ) in the transverse direction to the axis of the anchorable screw portion ( 20 ) are formed. The spinal implant of claim 1, wherein the head portion has a threaded portion ( 30 ) in the immediate vicinity of the mounting recess ( 28 ), wherein the nut element ( 52 ) in the threaded portion ( 30 ) of the head portion is screwed in, and wherein the nut element ( 52 ) has a formed with a Werkzeugingriffsnut upper, engageable with a drive tool wall. The spinal implant of claim 5, wherein the tool engagement groove (16) 56 ) one laterally on the distal end of the nut member ( 52 ) has formed transverse groove. Spinal implant according to claim 6, wherein the connecting rod ( 14 ) a ball engaging element ( 14A ) which is adapted to be received in the mounting recess of the head portion, wherein the spherical element ( 14A ) through the nut element ( 52 ) is held. A spinal implant according to claim 7, wherein the head portion comprises a pair of arcuate, vertical, with first parts of the ball element ( 14a ) engageable sections ( 18A . 18B ) having; and the nut element ( 52 ) an annular structure with a pair of arcuate, with second parts of the ball element ( 14a ) engageable engagement grooves such that the head portion of the implant body ( 18 ) and the nut element ( 52 ) a pivoting loading movement of the ball element ( 14A ) while maintaining the freedom of movement of the connecting rod ( 14 ) enable.